Antigen-specific stimulation of amino acid transport in bovine lymphocytes

Treatment of bovine lymphocytes isolated from animals which were either infected with Mycobacterium bovis or sensitized to a purified protein derivative (PPD-B) from this organism induced an increase in the transport of α-aminoisobutyric acid (AIB) and α-methylaminoisobutyric acid (MeAIB). PPD-B did not stimulate these transport activities in lymphocytes from nonsensitized animals. The transport stimulation was first measurable after about 7 hours of treatment, reached about a two-fold enhancement after 20 hours, and continued to increase to 30- to 40-fold after 6 days. The stimulation of AIB transport was inhibited by both ouabain and cycloheximide. Experiments to determine transport system specificities in nonstimulated lymphocytes showed that MeAIB transport was primarily by the Na⁺-dependent, A-system, and leucine transport was mostly by Na⁺-independent system(s). In contrast, AIB transport was about 25% by the A-system, 25% by at least one Na⁺-dependent, non-A-system, and 50% by one or more Na⁺-independent system(s). Analysis of the three components of AIB transport after treatment with PPD-B showed that: (1) transport by both the A-system and the Na⁺-independent system(s) was stimulated; (2) A-system transport was stimulated to a larger extent than Na⁺-independent transport; and (3) Na⁺-dependent, non-A-system transport was not stimulated significantly.     

A link between transport and plasma membrane redox system(s) in carrot cells

Carrot (Daucus carota L.) cells grown in suspension culture oxidized exogeneous NADH. The NADH oxidation was able to stimulate K⁺ (⁸⁶Rb⁺) transport into cells, but it did not affect sucrose transport.N,N'-Dicyclohexyl-carbodiimide, diethylstilbestrol, and oligomycin, which only partially inhibited NADH oxidation, almost completely collapsed the K⁺ (⁸⁶Rb⁺) transport. Vanadate, which is less effective as an ion transport inhibitor, was less effective in inhibiting the NADH-driven transport of K⁺ (⁸⁶Rb⁺).p-Fluormethoxycarbonylcyanide phenylhydrazone inhibits the K⁺ transport over 90% including that induced by NADH. The results are interpreted as evidence that a plasma membrane redox system in root cells is closely associated with the ATPase which can drive K⁺ transport. Because of the inhibitor effects, it appears that membrane components common to the redox system and ATPase function in the transport of K⁺.     

Superoxide dismutase: a photochemical augmentation assay.

Cell envelope vesicles containing bacteriorhodopsin, prepared from Halobacterium halobium, have previously been shown to accumulate glutamate to high concentration gradients when illuminated. This active transport is energized by a sodium gradient (Na_out⁺ ? Na_in⁺), which arises from Na⁺-efflux coupled to the light-induced H⁺-gradient. The oxidation of dimethyl phenylenediamine (DPD) by the vesicles also can drive uphill glutamate transport, and such transport is inhibited by KCN, azide, ionophores, or uncouplers. K_T for glutamate is 1.4 × 10^?7m under these conditions, as compared to 1.3 × 10^?7m for light-induced transport. The respiration-induced transport of glutamate is dependent on high Na⁺ concentrations on the vesicle exterior and requires low Na⁺ concentrations in the interior. When Na⁺ of increasing concentrations is included in the vesicles, transport proceeds with increasing lags, similarly to the case of light-driven transport. In vesicles to which DPD is added first, and then KCN at increasing time intervals (5 to 15 min), glutamate transport occurs after the addition of KCN, with increasing rates, even though respiration is inhibited. This indicates that the energy generated by DPD-oxidation is conserved over several minutes. These results suggest that in the case of respiration-dependent glutamate transport the translocation is also driven by a Na⁺-gradient; thus, there is a single glutamate transport system independent of the source of energy. The generation of such an Na⁺-gradient during DPD-oxidation implies that the respiration component involved, cytochrome oxidase, is functionally equivalent to bacteriorhodopsin, which acts as a proton pump.     

Rapid Stimulation of EAAC1-Mediated Na+-Dependent l-Glutamate Transport Activity in C6 Glioma Cells by Phorbol Ester

Abstract: C6 glioma cells were used as a model system to study the regulation of EAAC1-mediated Na⁺-dependent l -[³H]glutamate transport. Although a 30-min preincubation with forskolin had no effect on transport activity, preincubation with phorbol 12-myristate 13-acetate (PMA) increased transport activity two- to threefold. PMA caused a time-dependent and concentration-dependent increase in EAAC1-mediated l -[³H]glutamate transport activity. A 2-min preincubation with PMA was sufficient to cause more than a twofold increase in transport activity and the protein synthesis inhibitor cycloheximide had no effect on the increase. These data suggest that this increase is independent of protein synthesis. The EC₅₀ value of PMA for stimulation of transport activity was 80 nM. Kinetic analyses demonstrated that the increase in transport activity was due to a 2.5-fold increase in V_max with no change in K_m. PMA also increased the transport of the nonmetabolizable analogue, d -[³H]aspartate to the same extent. In parallel assays, PMA did not, however, increase Na⁺-dependent glycine transport activity in C6 glioma. The inactive phorbol ester 4α-phorbol 12,13-didecanoate, did not stimulate l -[³H]glutamate transport activity, and the protein kinase C inhibitor chelerythrine blocked the stimulation caused by PMA. Okadaic acid and cyclosporin A, which are phosphatase inhibitors, had no effect on the stimulation of transport activity caused by PMA. The Ca²⁺ ionophore A23187 did not act synergistically to increase PMA stimulation. In previous studies, PMA caused a rapid increase in amiloride-sensitive Na⁺/H⁺ transport activity in C6 glioma. In the present study, pre- and coincubation with amiloride had no effect on the stimulation of transport activity caused by PMA. These studies suggest that activation of protein kinase C causes a rapid increase in EAAC1-mediated transport activity. This rapid increase in Na⁺-dependent l -[³H]-glutamate transport activity may provide a novel mechanism for protection against acute insults to the CNS.     

Inhibition by amiloride of sodium transport into rabbit kidney medulla microsomes

Sodium transport into rabbit kidney medulla microsomes was 50% inhibited by amiloride. This Na⁺ uptake was shown to represent transport when the uptake process was reversed by the ionophore nigericin. The transport was complete within 60 min and proportional to the microsomal protein concentration. The effect of amiloride on transport was specific since the similar compound sulfaguanidine failed to affect microsomal Na⁺ transport. Amiloride-sensitive Na⁺ transport into microsomes was inhibited 70% by decreasing the pH (from 7.0 to 5.9), but was unaffected by the presence of a pH gradient. The kinetics of Na⁺ transport could be explained by a simple model, assuming that amiloride lowered the rate of Na⁺ entrance into the vesicles but had no effect on the rate of efflux. The failure of amiloride to effect efflux from the vesicles was also demonstrated directly.     

Water-Transporting Proteins

Transport through lipids and aquaporins is osmotic and entirely driven by the difference in osmotic pressure. Water transport in cotransporters and uniporters is different: Water can be cotransported, energized by coupling to the substrate flux by a mechanism closely associated with protein. In the K⁺/Cl⁻ and the Na⁺/K⁺/2Cl⁻ cotransporters, water is entirely cotransported, while water transport in glucose uniporters and Na⁺-coupled transporters of nutrients and neurotransmitters takes place by both osmosis and cotransport. The molecular mechanism behind cotransport of water is not clear. It is associated with the substrate movements in aqueous pathways within the protein; a conventional unstirred layer mechanism can be ruled out, due to high rates of diffusion in the cytoplasm. The physiological roles of the various modes of water transport are reviewed in relation to epithelial transport. Epithelial water transport is energized by the movements of ions, but how the coupling takes place is uncertain. All epithelia can transport water uphill against an osmotic gradient, which is hard to explain by simple osmosis. Furthermore, genetic removal of aquaporins has not given support to osmosis as the exclusive mode of transport. Water cotransport can explain the coupling between ion and water transport, a major fraction of transepithelial water transport and uphill water transport. Aquaporins enhance water transport by utilizing osmotic gradients and cause the osmolarity of the transportate to approach isotonicity.     

High Affinity Transport of CO(2) in the Cyanobacterium Synechococcus UTEX 625

The active transport of CO₂ in Synechococcus UTEX 625 was measured by mass spectrometry under conditions that preclude HCO₃⁻ transport. The substrate concentration required to give one half the maximum rate for whole cell CO₂ transport was determined to be 0.4 ± 0.2 micromolar (mean ± standard deviation; n = 7) with a range between 0.2 and 0.66 micromolar. The maximum rates of CO₂ transport ranged between 400 and 735 micromoles per milligram of chlorophyll per hour with an average rate of 522 for seven experiments. This rate of transport was about three times greater than the dissolved inorganic carbon saturated rate of photosynthetic O₂ evolution observed under these conditions. The initial rate of chlorophyll a fluorescence quenching was highly correlated with the initial rate of CO₂ transport (correlation coefficient = 0.98) and could be used as an indirect method to detect CO₂ transport and calculate the substrate concentration required to give one half the maximum rate of transport. Little, if any, inhibition of CO₂ transport was caused by HCO₃⁻ or by Na⁺-dependent HCO₃⁻ transport. However, ¹²CO₂ readily interfered with ¹³CO₂ transport. CO₂ transport and Na⁺-dependent HCO₃⁻ transport are separate, independent processes and the high affinity CO₂ transporter is not only responsible for the initial transport of CO₂ into the cell but also for scavenging any CO₂ that may leak from the cell during ongoing photosynthesis.     

Separate effects of mercurial compounds on the ionophoric and hydrolytic functions of the (Ca+++Mg++)-ATPase of sarcoplasmic reticulum

Summary We have shown that a Ca⁺⁺-ionophore activity is present in the (Ca⁺⁺+Mg⁺⁺)-ATPase of rabbit skeletal muscle sarcoplasmic reticulum (A.E. Shamoo & D.H. MacLennan, 1974.Proc. Nat. Acad. Sci. USA 71:3522). Methylmercuric chloride inhibited the (Ca⁺⁺+Mg⁺⁺)-ATPase and Ca⁺⁺ transport, but had no effect on the activity of the Ca⁺⁺ ionophore. Mercuric chloride inhibited ATPase, transport and ionophore activity. The ATPase and transport functions were more sensitive to methylmercuric chloride than to mercuric chloride. The two functions were inhibited concomitantly by methylmercuric chloride but slightly lower concentrations of mercuric chloride were required to inhibit Ca⁺⁺ transport than were required to inhibit ATPase. Methylmercuric chloride and mercuric chloride probably inhibited ATPase and Ca⁺⁺ transport by blocking essential-SH groups. However, it appears that there are no essential-SH groups in the Ca⁺⁺ ionophore and that mercuric chloride inhibited the Ca⁺⁺ ionophore activity by competition with Ca⁺⁺ for the ionophoric site. Blockage of Ca⁺⁺ transport by mercuric chloride probably occurs both at sites of essential-SH groups and at sites of ionophoric activity. These data suggest the separate identity of the sites of ATP hydrolysis and of Ca⁺⁺ ionophoric activity.     

Alanine and leucine transport in unfertilized pig oocytes and early blastocysts

Amino acid transport is facilitated by specific transporters within the plasma membrane of the cell. In mouse oocytes and cleavage-stage conceptus Na⁺-dependent L-alanine and L-leucine transport are nearly undetectable. Sodium-dependent transport via system B^O,+ in the mouse conceptus increases greatly between the 8-cell and blastocyst stages. By contrast, data presented here for the pig show that L-alanine and L-leucine transport is mainly Na⁺-dependent in the oocyte; this Na⁺-dependent component of transport becomes undetectable by the blastocyst stage. The Na⁺-dependent component of transport in oocytes is inhibited by BCH (2-aminoendo-bicyclo[2.2.1] hexane-2-carboxylic acid) and L-lysine and thus could be a form of system B^O,+. In both oocytes and blastocysts Na⁺-independent L-leucine transport is inhibited by BCH, which is consistent with the presence of system L. The dramatic decrease in Na⁺-dependent amino acid transport activity could occur in pig conceptuses in association with the onset of RNA synthesis during the 4-cell stage. Regardless of the precise time during development at which it occurs, however, this dramatic, developmentally regulated decrease in Na⁺-dependent alanine and leucine transport activity contrasts sharply with the large increase in Na⁺-dependent system B^O,+ activity that occurs during preimplantation development of murine conceptuses. Elucidation of the molecular mechanisms by which these changes occur should contribute to an understanding of regulation of gene expression during early development. © 1993 Wiley-Liss, Inc.     

Transport in halobacterium halobium: Light-induced cation-gradients,amino acid transport kinetics,and properties of transport carriers

Cell envelope vesicles prepared from H. halobium contain bacteriorhodopsin and upon illumination protons are ejected. Coupled to the proton motive force is the efflux of Na⁺. Measurements of ²²Na flux, exterior pH change, and membrane potential, ΔΨ (with the dye 3,3′-dipentyloxadicarbocyanine) indicate that the means of Na⁺ transport is sodium/proton exchange. The kinetics of the pH changes and other evidence suggests that the antiport is electrogenic (H⁺/Na⁺ > 1). The resulting large chemical gradient for Na⁺ (outside > inside), as well as the membrane potential, will drive the transport of 18 amino acids. The 19th, glutamate, is unique in that its accumulation is indifferent to ΔΨ: this amino acid is transported only when a chemical gradient for Na⁺ is present. Thus, when more and more NaCl is included in the vesicles glutamate transport proceeds with longer and longer lags. After illumination the gradient of H⁺ collapses within 1 min, while the large Na⁺ gradient and glutamate transporting activity persists for 10–15 min, indicating that proton motive force is not necessary for transport. A chemical gradient of Na⁺, arranged by suspending vesicles loaded with KCl in NaCl, drives glutamate transport in the dark without other sources of energy, with V_max and K_m comparable to light-induced transport. These and other lines of evidence suggest that the transport of glutamate is facilitated by symport with Na⁺, in an electrically neutral fashion, so that only the chemical component of the Na⁺ gradient is a driving force. The transport of all amino acids but glutamate is bidirectional. Actively driven efflux can be obtained with reversed Na⁺ gradients (inside > outside), and passive efflux is considerably enhanced by intravesicle Na⁺. These results suggest that the transport carriers are functionally symmetrical. On the other hand, noncompetitive inhibition of transport by cysteine (a specific inhibitor of several of the carriers) is only obtained from the vesicle exterior and only for influx: these results suggest that in some respects the carriers are asymmetrical. A protein fraction which binds glutamate has been found in cholate-solubilized H. halobium membranes, with an apparent molecular weight of 50,000. When this fraction (but not the others eluted from an Agarose column) is reconstituted with soybean lipids to yield lipoprotein vesicles, facilitated transport activity is regained. Neither binding nor reconstituted transport depend on the presence of Na⁺. The kinetics of the transport and of the competitive inhibition by glutamate analogs suggest that the protein fraction responsible is derived from the intact transport system.     

Errata

Mutants of Escherichia coli K-12 which are defective in components of transport systems for uracil and uridine were isolated and utilized to characterized the transport mechanism of uracil and uridine. Mutant U^?, isolated from a culture of the parent strain, is resistant to 5-fluorouracil and is deficient in the uracil transport system. Mutant UR^?, isolated from a culture of the parent strain, is resistant to a low concentration of showdomycin and lacks the capacity to transport intact uridine. Mutant U^?UR^?isolated from a culture of mutant U^?, is resistant to a low concentration of showdomycin and is defective in both uracil and intact uridine transport processes. Mutant UR^?R^? was isolated from a culture of mutant UR^?, and is resistant to high concentration of showdomycin. This mutant is defective for transport of intact uridine and in addition lacks the transport system for the ribose moiety of uridine. Characteristics of uracil and uridine transport in parent and mutant cells demonstrate the existence of specific transport processes for uracil, intact uridine and the uracil and ribose moieties of uridine. Mutants U^? and UR^?, which are defective for uracil transport, lack uracil phosphoribosyltransferase activity and retain a small but significant capacity to transport uracil. The data support the conclusion that uracil is transported by two mechanisms, the major one of which requires uracil phosphoribosyltransferase activity, while the other process involves the transport of uracil as such. The characteristics of uridine transport in parent and mutant strains show that, in addition to transport as the intact nucleoside, uridine is rapidly cleaved to the uracil and ribose moieties. The latter is transported into the cell by a process which, in contrast to transport of intact uridine, does not require an energy source. The uracil moiety is released into the medium and is transported by the uracil transport system. Whole cells of the parent and mutant strains differ in their ability to cleave uridine even though cell-free extracts of all the strains have similar uridine phosphorylase activity. The data implicate a uridine cleavage enzyme in a group transport of the ribose moiety of uridine, a process which is nonfunctional in mutants which lack the capacity to transport the ribose moiety of uridine. A common transport component for this process and the transport of intact uridine is indicated by similarities in the inhibitory effects of heterologous nucleosides on these process.     

Some characteristics of membrane Cd<Superscript>2+</Superscript> transport in rat thymocytes: an analysis using Fluo-3

Although cadmium-induced apoptosis of lymphocytes is one of common features in the immunotoxicity of cadmium, the membrane pathway for intracellular cadmium accumulation is not fully elucidated. To characterize membrane Cd²⁺ transport of rat thymocytes, the change in intracellular Cd²⁺ concentration under various conditions was examined by the use of Fluo-3, a fluorescent probe for monitoring the change in intracellular concentration of divalent metal cations. The membrane Cd²⁺ transport was estimated by the augmentation of Fluo-3 fluorescence induced by bath application of CdCl₂. Lowering temperature strongly suppressed the augmentation of Fluo-3 fluorescence by CdCl₂, suggesting that the metabolic process can be involved in membrane Cd²⁺ transport. External acidification (decreasing pH) and membrane depolarization by adding KCl attenuated the augmentation, indicating the requirement of electrochemical driving force for membrane Cd²⁺ transport into the cells. Bath application of CaCl₂ and ZnCl₂ equally decreased the augmentation, suggesting their competition with Cd²⁺ at the membrane transport. The augmentation by CdCl₂ was lesser in the cells treated with N-ethylmaleimide inducing chemical depletion of cellular thiols. The result suggests the contribution of sulfhydryl groups to membrane Cd²⁺ transport. Taken together, it is suggested that the cells possess a temperature-sensitive membrane Cd²⁺ pathway, driven by electrochemical gradient of Cd²⁺ and transmembrane potential, with competitive binding site. Based on the characteristics described above, it is unlikely that the membrane Cd²⁺ transport in rat thymocytes is attributed to a single transport system although it has characteristics that are similar to those of divalent cation transporter 1.     

Loading and transport of assimilates in different maize leaf bundles

The loading and transport functions of vascular bundles in maize (Zea mays L.) leaf strips were investigated by microautoradiography after application of ¹⁴CO₂. The concentrations of ¹⁴C-contents in thin-walled sieve tubes of individual bundles in the loading and transport regions were determined by digital image analysis of silver-grain density over the sieve tubes and compared. In the loading region, relatively high concentrations of ¹⁴C-contents were found in the thin-walled sieve tubes of small bundles and in the small, thin-walled sieve tubes of the intermediate bundles; the concentration of ¹⁴C-label in large bundles was very low. In the transport region, at a transport distance of 2 cm, all of the small bundles contained ¹⁴C-assimilates, but generally less than the same bundles did in the loading region; by comparison, at that distance intermediate and large bundles contained two-to threefold more ¹⁴C-assimilates than the same bundles in the loading region. The lateral transfer of assimilates from smaller to larger bundles via transverse veins could be demonstrated directly in microautoradiographs. A reverse transport from larger to smaller bundles was not found. At a transport distance of 4 cm, all large and intermediate bundles were ¹⁴C-labeled, but many of the small bundles were not. Although all longitudinal bundles were able to transport ¹⁴C-asimilates longitudinally down the blade, it was the large bundles that were primarily involved with longitudinal transport and the small bundles that were primarily involved with loading.     

Dual effect of adrenalin on sugar transport in rat diaphragm muscle

The effect of adrenalin on the membrane transport of the non-metabolized sugar, 3-methylglucose, was studied in isolated “intact” rat hemidiaphragms and related to simultaneously occurring changes in the internal levels of Na⁺, ATP, glucose-6-P, glycerol formation and ⁴⁵Ca uptake and loss. Basal sugar transport was inhibited by low (10⁻⁸−10⁻⁵ M) concentrations of adrenalin; this was antagonized by propranolol and practolol. High concentrations (10⁻⁴−10⁻³ M) stimulated sugar transport, and this was blocked by propranolol and butoxamine and was dependent on external Ca²⁺. These results suggest interaction with two different classes of adrenergic receptors, possibly of β₁ and β₂ types. Both low and high concentrations increased Na⁺ and K⁺ gradients by a practolol-sensitive effect. Isoproterenol behaved identically but phenylephrine had only the two practolol-sensitive effects on sugar and ion transport. Insulin did not interfere with inhibition of sugar transport and decrease in internal Na⁺ but prevented stimulation of sugar transport. Under anoxia adrenalin had no effect on sugar transport but led to greater Na⁺ gain by tissue. Addition of 3.0 mM palmitate decreased inhibition of sugar transport without changing receptor specificity. ATP was decreased and lipolysis enchanged by high adrenalin but glucose-6-P was increased by the low concentration as well. Influx of ⁴⁵Ca was decreased by low and increased by high adrenalin; ⁴⁵Ca efflux was also differentially affected. The results indicate that inhibition and stimulation of sugar transport depend on different receptors and that the latter response may override the former. The data are consistent with the earlier postulated regulatory role of sarcoplasmic Ca²⁺ on sugar transport in muscle, with adrenalin affecting Ca²⁺ fluxes and distribution both directly and indirectly.     

Coupled transepithelial sodium and potassium transport across isolated frog skin: Effect of ouabain,amiloride and the polyene antibiotic filipin

Summary Addition of the polyene antibiotic filipin (50 m) to the outside bathing solution (OBS) of the isolated frog skin resulted in a highly significant active outward transport of K⁺ because filipinper se increases the nonspecific Na⁺ and K⁺ permeability of the outward facing membrane. The K⁺ transport was calculated from the chemically determined changes in K⁺ concentrations in the solution bathing the two sides of the skin. The active transepithelial K⁺ transport required the presence of Na⁺ in the OBS, but not in the inside bathing solution (IBS), and it was inhibited by the Na⁺, K⁺-ATPase inhibitor ouabain. The addition of Ba⁺⁺ to the IBS in the presence of filipin in the OBS resulted in an activation of the transepithelial K⁺ transport and in an inhibition of the active Na⁺ transport. This is in agreement with the notion that Ba⁺⁺ decreases the passive K⁺ permeability of the inward facing membrane. In the presence of amiloride (which blocks the specific Na permeability of the outward facing membrane) and Ba⁺⁺ there was a good correlation between the active Na⁺ and K⁺ transport. It is concluded that the active transepithelial K⁺ transport is carried out by a coupled electrogenic Na–K pump, and it is suggested that the pump ratio (Na/K) is 1.5.     

Electrogenic transport of 5-oxoproline in rabbit renal brush-border membrane vesicles Effect of intravesicular potassium

The Na⁺-dependent transport of 5-oxoproline into rabbit renal brush-border vesicles was stimulated by a K⁺ diffusion potential (interior-negative) induced by valinomycin. Na⁺ salts of two anions of different epithelial permeabilities also affected 5-oxoproline transport. These results show that the Na⁺-dependent 5-oxoproline transport in renal brush-border vesicles is an electrogenic process which results in a net transfer of positive charge. Maximum transport of 5-oxoproline occurred at an extravesicular pH of 6.0 to 8.0 and over that pH range, 5-oxoproline exists completely as an anion with a negative charge. The simplest stoichiometry consistent with this process is, therefore, the cotransport of one 5-oxoproline anion with two sodium ions. The presence of K⁺ inside the vesicles stimulated the Na⁺-dependent transport of 5-oxoproline. This stimulatory effect was specific for K⁺ and required the presence of Na⁺. The presence of Na⁺ gradient was not mandatory for the K⁺ action. The stimulation by the intravesicular K⁺ was seen in the presence as well as in the absence of a K⁺ gradient. Therefore, the increased influx of 5-oxoproline was not coupled to the simultaneous efflux of K⁺. The presence of K⁺ in the extravesicular medium alone did not affect the Na⁺-dependent transport of 5-oxoproline, showing that the site of K⁺ action was intravesicular. Glutamate did not interact with the Na⁺-dependent 5-oxoproline transport even in the presence of an outward K⁺ gradient.     

Corneal endothelium transports fluid in the absence of net solute transport

The corneal endothelium transports fluid from the corneal stroma to the aqueous humor, thus maintaining stromal transparency by keeping it relatively dehydrated. This fluid transport mechanism is thought to be driven by the transcellular transports of HCO₃⁻ and Cl⁻ in the same direction, from stroma to aqueous. In parallel to these anion movements, for electroneutrality, there are paracellular Na⁺ and transcellular K⁺ transports in the same direction. The resulting net flow of solute might generate local osmotic gradients that drive fluid transport. However, there are reports that some 50% residual fluid transport remains in nominally HCO₃⁻ free solutions. We have examined the driving force for this residual fluid transport. We confirm that in nominally HCO₃⁻ free solutions, 48% of control fluid transport remains. When in addition Cl⁻ channels are inhibited, 30% of control fluid movement still remains. Addition of a carbonic anhydrase inhibitor has no further effect. These manipulations combined inhibit the transcellular transport of all anions, without which there cannot be any net transport of solute and consequently no local osmotic gradients, yet there is residual fluid movement. Only the further addition of benzamil, an inhibitor of epithelial Na⁺ channels, abolishes fluid transport completely. Our data are inconsistent with transcellular local osmosis and instead support the paradigm of paracellular fluid transport driven by electro-osmotic coupling.     

Serosal Na/Ca exchange and H+ and Na+ transport by the turtle and toad bladders

Summary A Na/Ca exchange system has been described in the plasma membrane of several tissues and seems to regulate the concentration of calcium in cytosol. Replacement of extracellular Na by sucrose increases calcium uptake into and decreases calcium efflux from the cell, leading to an increase in cytosolic calcium. The effect of an increase in cytosolic calcium mediated by the Na/Ca exchange system on H⁺ and Na transport in the turtle and toad bladder was investigated by replacing serosal Na isosmotically by sucrose or choline. Replacement of serosal by sucrose was associated with a significant inhibition of H⁺ secretion or Na transport which was reversible by addition of NaCl. Replacement of mucosal Na by sucrose failed to alter H⁺ secretion. Removal of serosal Na was associated with a significant increase in⁴⁵Ca uptake which could be blocked by pretreatment with lanthanum chloride. Pretreatment with lanthanum chloride blunted the inhibitory effect of replacement of serosal Na by sucrose on H⁺ and Na transport, thus suggesting that the increase in calcium uptake and the inhibition of transport are causally related. Under anaerobic conditions the rate of H⁺ or Na transport are linked to the rate of lactate production. The inhibition of Na or H⁺ transport by removal of serosal Na was accompanied by a proportional decrease in lactate production, thus suggesting that an increase in cytosolic calcium does not inhibit transport by uncoupling glycolysis from transport. Replacement of serosal Na by sucrose did not alter the force of the H⁺ or Na pump but led to an increase in resistance of the active pathway of H⁺ and Na transport. The inhibition of Na transport by replacement of serosal Na with sucrose could be reversed by addition of amphotericin B, an agent which increases luminal permeability to Na, thus suggesting that decreased Na entry across the apical membrane is the mechanism responsible for the inhibition of Na transport. The results of the present studies strongly suggest that an increase in cytosolic calcium through the serosal Na/Ca exchange system inhibits H⁺ and Na transport in the turtle and toad bladder probably by increasing the resistance of the luminal membrane.     

Taurine transport by brush border membrane vesicles isolated from the flounder kidney

Summary Taurine transport was investigated in brush border membrane vesicles isolated from renal tubules of the winter flounder (Pseudopleuronectes americanus). Taurine uptake by the vesicles was greater in the presence of NaCl as compared to uptake in KCl. The Na⁺-dependent taurine transport was electrogenic and demonstrated tracer replacement and inhibition by -alanine and HgCl₂, indicating the presence of Na⁺-dependent, carrier-mediated taurine transport. In contrast to Na⁺-dependent taurine transport across the basolateral membrane, there was not a specific Cl^– dependency for transport in the brush border membrane. No evidence was obtained for Na⁺-independent carrier-mediated taurine transport. The possible involvement of the brush border Na⁺-dependent transport system in the net secretion of taurine from blood to tubular lumen in vivo (Schrock et al. 1982) is discussed.     

Neutral amino acid transport in surface membrane vesicles isolated from mouse fibroblasts: Intrinsic and extrinsic models of regulation

Membrane transport carrier function, its regulation and coupling to metabolism, can be selectively investigated dissociated from metabolism and in the presence of a defined electrochemical ion gradient driving force, using the single internal compartment system provided by vesiculated surface membranes. Vesicles isolated from nontransformed and Simian virus 40-transformed mouse fibroblast cultures catalyzed carrier-mediated transport of several neutral amino acids into an osmotically-sensitive intravesicular space without detectable metabolic conversion of substrate. When a Na⁺ gradient, external Na⁺ > internal Na⁺, was artifically imposed across vesicle membranes, accumulation of several neutral amino acids achieved apparent intravesicular concentrations 6- to 9-fold above their external concentrations. Na⁺-stimulated alanine transport activity accompanied plasma membrane material during subcellular fractionation procedures. Competitive interactions among several neutral amino acids for Na⁺-stimulated transport into vesicles and inactivation studies indicated that at least 3 separate transport systems with specificity properties previously defined for neutral amino acid transport in Ehrlich ascites cells were functional in vesicles from mouse fibroblasts: the A system, the L system and a glycine transport system. The pH profiles and apparent K_m values for alanine and 2-aminoisobutyric acid transport into vesicles were those expected of components of the corresponding cellular uptake system. Several observations indicated that both a Na⁺ chemical concentration gradient and an electrical membrane potential contribute to the total driving force for active amino acid transport via the A system and the glycine system. Both the initial rate and quasi-steady-state of accumulation were stimulated as a function of increasing concentrations of Na⁺ applied as a gradient (external > internal) across the membrane. This stimulation was independent of endogenous Na⁺, K⁺-ATPase activity in vesicles and was diminished by monensin or by preincubation of vesicles with Na⁺. The apparent K_m for transport of alanine and 2-aminoisobutyric acid was decreased as a function of Na⁺ concentration. Similarly, in the presence of a standard initial Na⁺ gradient, quasi-steady-state alanine accumulation in vesicles increased as a function of increasing magnitudes of interior-negative membrane potential imposed across the membrane by means of K⁺ diffusion potentials (internal > external) in the presence of valinomycin; the magnitude of this electrical component was estimated by the apparent distributions of the freely permeant lipophilic cation triphenylme thylphosphonium ion. Alanine transport stimulation by charge asymmetry required Na⁺ and was blocked by the further addition of either nigericin or external K⁺. As a corollary, Na⁺-stimulated alanine transport was associated with an apparent depolarization, detectable as an increased labeled thiocyanate accumulation. Permeant anions stimulated Na⁺-coupled active transport of these amino acids but did not affect Na⁺-independent transport. Translocation of K⁺, H⁺, or anions did not appear to be directly involved in this transport mechanism. These characteristics support an electrogenic mechanism in which amino acid translocation is coupled t o an electrochemical Na⁺ gradient by formation of a positively charged complex, stoichiometry unspecified, of Na⁺, amino acid, and membrane component. Functional changes expressed in isolated membranes were observed t o accompany a change in cellular proliferative state or viral transformation. Vesicles from Simian virus 40-transformed cells exhibited an increased Vmax of Na⁺-stimulated 2-aminoisobutyric acid transport, as well as an increased capacity for steady-state accumulation of amino acids in response t o a standard Na⁺ gradient, relative t o vesicles from nontransformed cells. Density-inhibition of nontransformed cells was associated with a marked decrease in these parameters assayed in vesicles. Several possibilities for regulatory interactions involving gradient-coupled transport systems are discussed.